Complex functional phenotypes of NMDA receptor disease variants

NMDA receptors have essential roles in the physiology of central excitatory synapses and their dysfunction causes severe neuropsychiatric symptoms. Recently, a series of genetic variants have been identified in patients, however, functional information about these variants is sparse and their role i...

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Veröffentlicht in:	Molecular psychiatry 2022-12, Vol.27 (12), p.5113-5123
Hauptverfasser:	Iacobucci, Gary J., Liu, Beiying, Wen, Han, Sincox, Brittany, Zheng, Wenjun, Popescu, Gabriela K.
Format:	Artikel
Sprache:	eng
Schlagworte:	13/109 631/337 631/378 631/45 692/699/476 9/74 Amino acid sequence Behavioral Sciences Binding sites Biological Psychology Channel gating Electrophysiological Phenomena Electrophysiology Genetic diversity Glutamic acid receptors (ionotropic) Ligands Medicine Medicine & Public Health Mental disorders Molecular dynamics Mutation N-Methyl-D-aspartic acid receptors Neurosciences Permeability Pharmacotherapy Phenotype Phenotypes Physiology Psychiatry Receptor mechanisms Receptors, N-Methyl-D-Aspartate - genetics Software Synapses
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creator	Iacobucci, Gary J. Liu, Beiying Wen, Han Sincox, Brittany Zheng, Wenjun Popescu, Gabriela K.
description	NMDA receptors have essential roles in the physiology of central excitatory synapses and their dysfunction causes severe neuropsychiatric symptoms. Recently, a series of genetic variants have been identified in patients, however, functional information about these variants is sparse and their role in pathogenesis insufficiently known. Here we investigate the mechanism by which two GluN2A variants may be pathogenic. We use molecular dynamics simulation and single-molecule electrophysiology to examine the contribution of GluN2A subunit-residues, P552 and F652, and their pathogenic substitutions, P552R and F652V, affect receptor functions. We found that P552 and F652 interact during the receptors’ normal activity cycle; the interaction stabilizes receptors in open conformations and is required for a normal electrical response. Engineering shorter side-chains at these positions (P552A and/or F652V) caused a loss of interaction energy and produced receptors with severe gating, conductance, and permeability deficits. In contrast, the P552R side chain resulted in stronger interaction and produced a distinct, yet still drastically abnormal electrical response. These results identify the dynamic contact between P552 and F652 as a critical step in the NMDA receptor activation, and show that both increased and reduced communication through this interaction cause dysfunction. Results show that subtle differences in NMDA receptor primary structure can generate complex phenotypic alterations whose binary classification is too simplistic to serve as a therapeutic guide.
doi_str_mv	10.1038/s41380-022-01774-6
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Recently, a series of genetic variants have been identified in patients, however, functional information about these variants is sparse and their role in pathogenesis insufficiently known. Here we investigate the mechanism by which two GluN2A variants may be pathogenic. We use molecular dynamics simulation and single-molecule electrophysiology to examine the contribution of GluN2A subunit-residues, P552 and F652, and their pathogenic substitutions, P552R and F652V, affect receptor functions. We found that P552 and F652 interact during the receptors’ normal activity cycle; the interaction stabilizes receptors in open conformations and is required for a normal electrical response. Engineering shorter side-chains at these positions (P552A and/or F652V) caused a loss of interaction energy and produced receptors with severe gating, conductance, and permeability deficits. 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title	Complex functional phenotypes of NMDA receptor disease variants
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